More than a million ways to be pushed. A high-fidelity experimental dataset of planar pushing

Yu, Kuan-Ting; Bauzá, Maria; Fazeli, Nima; Rodríguez, Alberto

doi:10.1109/iros.2016.7758091

Cited by 141 publications

(172 citation statements)

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“…Since we presented our earlier dataset on planar pushing [1], it has been directly used for: 1) Stochastic modeling: [23,10,17] 2) Modeling from rendered images: [16] 3) Model identification: [24] 4) Learning models for control: [25,26] 5) Filtering: [27] 6) Meta-learning: [28] With this new dataset we hope to further facilitate research in learning models and control.…”

Section: Related Workmentioning

confidence: 99%

Omnipush: accurate, diverse, real-world dataset of pushing dynamics with RGB-D video

Bauzá

Alet

Lin

et al. 2019

2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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Pushing is a fundamental robotic skill. Existing work has shown how to exploit models of pushing to achieve a variety of tasks, including grasping under uncertainty, in-hand manipulation and clearing clutter. Such models, however, are approximate, which limits their applicability.Learning-based methods can reason directly from raw sensory data with accuracy, and have the potential to generalize to a wider diversity of scenarios. However, developing and testing such methods requires rich-enough datasets. In this paper we introduce Omnipush, a dataset with high variety of planar pushing behavior.In particular, we provide 250 pushes for each of 250 objects, all recorded with RGB-D and a high precision tracking system. The objects are constructed so as to systematically explore key factors that affect pushing -the shape of the object and its mass distribution-which have not been broadly explored in previous datasets, and allow to study generalization in model learning.Omnipush includes a benchmark for meta-learning dynamic models, which requires algorithms that make good predictions and estimate their own uncertainty. We also provide an RGB video prediction benchmark and propose other relevant tasks that can be suited with this dataset. Data and code are available at https://web.mit.edu/mcube/omnipush-dataset/.

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Section: Related Workmentioning

confidence: 99%

Omnipush: accurate, diverse, real-world dataset of pushing dynamics with RGB-D video

Bauzá

Alet

Lin

et al. 2019

2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

Self Cite

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“…Datasets that have been collected through the use of motion capture include human pose estimation [20], interactive manipulation performed by a human [21] and sequences of labelled RGB-D images for SLAM [1]. More specifically for tasks by robot manipulators, there are motion capture datasets of robots performing planar pushing and datasets of rigid body contacts, but here the emphasis is on tracking the effects of the robot in the context of a task, not the robot itself [22], [23]. Tracking of a dexterous manipulator to overcome the reality gap is similar to what we propose, however this information isn't available as a re-usable benchmark dataset [24].…”

Section: Related Workmentioning

confidence: 99%

Benchmarking Simulated Robotic Manipulation Through a Real World Dataset

Collins

McVicar

Wedlock

et al. 2020

IEEE Robot. Autom. Lett.

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We present a benchmark to facilitate simulated manipulation; an attempt to overcome the obstacles of physical benchmarks through the distribution of a real world, ground truth dataset. Users are given various simulated manipulation tasks with assigned protocols having the objective of replicating the real world results of a recorded dataset. The benchmark comprises of a range of metrics used to characterise the successes of submitted environments whilst providing insight into their deficiencies.We apply our benchmark to two simulation environments, PyBullet and V-Rep, and publish the results. All materials required to benchmark an environment, including protocols and the dataset, can be found at the benchmarks' website 1 .

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“…the Peshkin bound [13]. We test the bounds over the objects in the MIT Pushing Dataset [17] and randomly generated bipods, tripods, and quadrapods. The generated n-pods were chosen to have circumcircle diameters similar to the MIT objects, roughly 0.16m.…”

Section: Experiments a Comparison Of Angular Velocity Boundsmentioning

confidence: 99%

“…First, pressure distributions of objects are statically indeterminant (barring the case of three-point support with known center of mass). Second, surface imperfections lead to spatial variability in both the pressure distribution and coefficient of friction [17]. Though several force-motion models for pushing exist [19,7,4], the above sources of indeterminacy ultimately lead to errors in the predicted velocity of the pushed object.…”

Section: Introductionmentioning

confidence: 99%

Exact Bounds on the Contact Driven Motion of a Sliding Object, With Applications to Robotic Pulling

Huang

Bhatia

Boots

et al. 2017

Robotics: Science and Systems XIII

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Abstract-This paper explores the quasi-static motion of a planar slider being pushed or pulled through a single contact point assumed not to slip. The main contribution is to derive a method for computing exact bounds on the object's motion for classes of pressure distributions where the center of pressure is known but the distribution of support forces is unknown. The second contribution is to show that the exact motion bounds can be used to plan robotic pulling trajectories that guarantee convergence to the final pose. The planner was tested on the task of pulling an acrylic rectangle to random locations within the robot workspace. The generated plans were accurate to 4.00mm ± 3.02mm of the target position and 4.35 degrees ± 3.14 degrees of the target orientation.

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More than a million ways to be pushed. A high-fidelity experimental dataset of planar pushing

Cited by 141 publications

References 30 publications

Omnipush: accurate, diverse, real-world dataset of pushing dynamics with RGB-D video

Omnipush: accurate, diverse, real-world dataset of pushing dynamics with RGB-D video

Benchmarking Simulated Robotic Manipulation Through a Real World Dataset

Exact Bounds on the Contact Driven Motion of a Sliding Object, With Applications to Robotic Pulling

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